A New RadMon Version for the LHC&lt;newline/&gt; and its Injection Lines

Spiezia, G.; Peronnard, P.; Masi, A.; Brügger, M.; Brucoli, M.; Danzeca, Salvatore; Alía, Rubén García; Losito, R.; Mekki, Julien; Oser, Pascal; Gaillard, R.; Dusseau, L.

doi:10.1109/tns.2014.2365046

Cited by 73 publications

(30 citation statements)

References 11 publications

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“…The total time of irradiation was approx. 112 h. During this time the SUT received a total high-energy hadron equivalent (HEHeq) fluence of 2.170 × 10 11 #/cm 2 and a TID of 9.25 krad(Si), as measured by local on-line monitoring by means of the RadMON system [9]. In addition to the general reboot and power-cycle events, the internal monitored voltages and currents of the housekeeping data set have been analyzed as presented in Figure 7.…”

Section: Resultsmentioning

confidence: 99%

In-Situ Testing of a Multi-Band Software-Defined Radio Platform in a Mixed-Field Irradiation Environment

Budroweit¹,

Mueller

Jaksch³

et al. 2019

Aerospace

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This paper presents an in-situ test concept for a multi-band software-defined radio (SDR) platform in a mixed-field radiation environment. Special focus is given to the complex automated test setup with respect to the requirements of the irradiation facility. Additionally, selected test results of a system-level evaluation are presented and discussed. For the verification of the mixed-field radiation environment, the software-defined radio (SDR) was also tested under proton irradiation. The cross-sections for the observed single event effects are compared and show similar results.

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Section: Resultsmentioning

confidence: 99%

In-Situ Testing of a Multi-Band Software-Defined Radio Platform in a Mixed-Field Irradiation Environment

Budroweit¹,

Mueller

Jaksch³

et al. 2019

Aerospace

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“…ACCELERATOR ENVIRONMENT The high-energy accelerator radiation environment is a complex field composed of a broad variety of particles and energies [8], [9], which is typically modeled through advanced Monte Carlo geometries and simulations using the FLUKA tool [13] and monitored by means of the RadMON system [14]. In such an environment, single-event effects (SEEs) in accelerator systems (e.g., magnet powering and protection, beam instrumentation, cryogenics, vacuum, and so on) largely based on COTS components can be highly critical to the performance and availability of the machine [15].…”

Section: Low-energy Charged Particles In Thementioning

confidence: 99%

Direct Ionization Impact on Accelerator Mixed-Field Soft-Error Rate

Alía

Gilardoni

Infantino

et al. 2020

IEEE Trans. Nucl. Sci.

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“…Particles scattered from a Cu target, including gamma rays, charged particles, neutrons, and other hadrons, will hit the components under test. Total ionization dose (TID) and neutrons are measured by the RadMon, which was placed near the amplifiers [29]. Another amplifier using LDMOS was also tested, as described in Section III-B.…”

Section: E Mixed-field Radiation Test At the Charm Facilitymentioning

confidence: 99%

Development of Radiation-Hard Solid-State Amplifiers for Kilogray Environments Using COTS Components

Ohmori

Paoluzzi

2019

IEEE Trans. Nucl. Sci.

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The high-luminosity Large Hadron Collider (LHC) (HL-LHC) project is the upgrade of the LHC to increase its luminosity by a factor of 5 compared with the nominal value. The LHC injector upgrade (LIU) project aims at upgrading the LHC injector chain to reach the goal of the HL-LHC. The LIU project covers all injectors, that is, the Linac 4, proton synchrotron (PS) booster (PSB), PS, and super PS (SPS). In the PSB, the present ferrite-loaded RF accelerating systems will be replaced with magnetic alloy (Finemet)-loaded cavity systems. The cavity system allows the implementation of a cellular topology and the use of solid-state RF power amplifiers. The PSB will have 144 cavity cells and amplifiers, and each amplifier uses 17 high-power MOSFETs. The RF systems will be installed in the straight sections where the total ionization dose (TID) is 20 Gy(Si)/year, which may even increase after the upgrade. Research and development work has been performed to validate the use of solid-state amplifiers in this radioactive environment. In this article, we describe a technique to stabilize the solidstate amplifier up to the total dose of about 10 kGy. This technique will enable the use of solid-state amplifiers in even higher radiation environments. The higher sensitivity to the single-event effects (SEEs) of the laterally diffused metal-oxide semiconductors (LDMOS) than to that of the vertical metaloxide-semiconductor (VMOS) devices is also reported.

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A New RadMon Version for the LHC<newline/> and its Injection Lines

Abstract: International audienc

Cited by 73 publications

References 11 publications

In-Situ Testing of a Multi-Band Software-Defined Radio Platform in a Mixed-Field Irradiation Environment

In-Situ Testing of a Multi-Band Software-Defined Radio Platform in a Mixed-Field Irradiation Environment

Direct Ionization Impact on Accelerator Mixed-Field Soft-Error Rate

Development of Radiation-Hard Solid-State Amplifiers for Kilogray Environments Using COTS Components

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